Authors: Maris Klavins, Valery Rodinov

Abstract:

The aim of this study was to analyze long term changes of surface water quality in Latvia, spatial variability of water chemical composition, possible impacts of different pollution sources as well as to analyze the measures to protect national water resources - river basin management. Within this study, the concentrations of major water ingredients and microelements in major rivers and lakes of Latvia have been determined. Metal concentrations in river and lake waters were compared with water chemical composition. The mean concentrations of trace metals in inland waters of Latvia are appreciably lower than the estimated world averages for river waters and close to or lower than background values, unless regional impacts determined by local geochemistry. This may be explained by a comparatively lower level of anthropogenic load. In the same time in several places, direct anthropogenic impacts are evident, regarding influences of point sources both transboundary transport impacts. Also, different processes related to pollution of surface waters in Latvia have been analyzed. At first the analysis of changes and composition of pollutant emissions in Latvia has been realized, and the obtained results were compared with actual composition of atmospheric precipitation and their changes in time.

Keywords: Water quality, trend analysis, pollution, human impact.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1131533

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 947

References:

[1] A. Räike, O. P. Pietilainen, S. Rekolainen, P. Kauppila, H. Pitkanen, J. Niemi, A. Raateland. and J. Vuorenmaa 2003. Trends of phosphorus, nitrogen and chlorophyll a concentrations in Finnish rivers and lakes in 1975 – 2000. Science of the Total Environment vol. 310, pp. 47 – 59.
[2] R. Donohue, A.W. Davidson, N.E. Peters, S. Nelson and B. Jakowyna 2001. Trends in total phosphorus and total nitrogen concentrations of tributaries to the Swan-Canning Estuary, 1987 to 1998. Hydrologic Processes vol. 15, pp. 2411-2434.
[3] D. F. Brakke, D. H. Landers and Eilers J. M. 1988. Chemical and physical characteristics of lakes in the Northeastern United States. Environmental Science and Technology vol. 22(2), pp. 155-163.
[4] K. S. Godwin, S. D. Hafner and Buff M.F. 2003. Long-term trends in sodium and chloride in the Mohawk River, New York: the effect of fifty years of road-salt application. Environmental Pollution vol. 124, pp. 273-281.
[5] P. Stålnacke, A. Grimvall, C. Libiseller, M. Laznik M. and Kokorite I. 2003. Trends in nutrient concentrations in Latvian rivers and the response to the dramatic change in agriculture. Journal of Hydrology vol. 283, pp. 184-205.
[6] M. Klavins, A. Briede, E. Parele, V. Rodinov. & Klavina I. 1998a. Metal accumulation in sediments and benthic invertebrates in lakes of Latvia. Chemosphere vol. 36(15), pp. 3043-3053.
[7] T. Juhna and Klavins M. 2001. Water quality changes in Latvia and Riga. 1980 – 2000: possibilities and constraints. Ambio vol. 30, pp. 326-331.
[8] M. Klavins, A. Briede, V. Rodinov, I. Kokorite and Frisk T. 2002. Long-term changes of the river runoff in Latvia. Boreal Environment Research vol. 7(4), pp. 447-457.
[9] Standard Methods for the Examination of Water and Wastewater 2012 21th edn, American Public Health Association/American Water Works Association/Water Environment Federation, Washington DC, USA
[10] R. M. Hirsch and Slack J.R. 1984. A nonparametric trend test for seasonal data with serial dependence. Water Resources Research vol. 20(6), pp. 727-732.